KR102323921B1 - Apparatus for Manufacturing Copper Foil - Google Patents

Abstract

The present invention relates to a copper foil manufacturing apparatus comprising: an electrodeposition unit for electrodepositing an electrodeposited copper foil; a supply unit for supplying a support structure including a carrier film and a release film formed on the carrier film; a laminating unit for laminating the electrodeposited copper foil supplied from the electrodeposition unit and the support structure supplied from the supply unit; and a winding unit for winding the copper foil laminated by the laminating unit. The supply unit includes: a supply roller on which the carrier film is wound; and a forming device disposed between the supply roller and the laminating unit to form the release film on the carrier film to manufacture the support structure. An objective of the present invention is to provide the copper foil manufacturing apparatus capable of reducing a process time for manufacturing a deformable copper foil.

Description

Copper Foil Manufacturing Equipment {Apparatus for Manufacturing Copper Foil}

The present invention relates to a copper foil manufacturing apparatus for manufacturing a copper foil used for manufacturing various products such as a negative electrode for a secondary battery and a flexible printed circuit board.

Copper foil (銅箔) is used to manufacture various products such as anodes for secondary batteries and flexible printed circuit boards (FPCBs). This copper foil is manufactured through an electroplating method in which an electrolytic solution is supplied between an anode and a cathode and then an electric current flows.

As a method for manufacturing such a copper foil to a thinner thickness, there is a method of manufacturing a copper foil having a release layer attached thereto (hereinafter referred to as 'release copper foil') using a carrier film and a release layer. According to this, by forming a copper foil layer on the release layer after forming the release layer on the carrier film, the release copper foil is manufactured. The release copper foil manufactured as described above can be manufactured to a thinner thickness because the carrier film functions as a support, and even when the copper foil is manufactured to have a thinner thickness, it is easy to transport and has improved handling properties.

1 is a conceptual diagram of a copper foil manufacturing apparatus according to the prior art.

1, the copper foil manufacturing apparatus 10 according to the prior art includes a winding roller 11 for unwinding a carrier film, a winding roller 12 for winding a release copper foil, the unwinding roller 11 and the winding roller It includes a plurality of immersion tanks (13) disposed between (12). Among the immersion tanks 13 , the first immersion tub 13a and the second immersion tub 13b are for forming a release layer. Among the immersion baths 13, the third immersion bath 13c is for forming a copper foil layer.

As the carrier film unwound from the unwinding roller 11 sequentially passes through the first immersion tank 13a and the second immersion tank 13b, a release layer is formed on the carrier film. Then, while the carrier film on which the release layer is formed passes through the third immersion tank 13c, a copper foil layer is formed on the release layer. Accordingly, the release layer is formed on the carrier film and the release copper foil in which the copper foil layer is formed on the release layer is wound on the winding roller 12 .

As such, in the copper foil manufacturing apparatus 1 according to the prior art, the carrier film must pass through a plurality of immersion baths 13 in sequence, and the release layer, the copper foil layer, etc. are formed in each of the immersion baths 13 . time must be secured. Therefore, in the copper foil manufacturing apparatus 1 according to the prior art, since the process time for manufacturing the deformable copper foil increases, there is a problem in that the productivity of the deformable copper foil is low.

The present invention has been devised to solve the above-described problems, and to provide a copper foil manufacturing apparatus capable of reducing the process time for manufacturing a deformed copper foil.

In order to solve the above problems, the present invention may include the following configuration.

An apparatus for manufacturing copper foil according to the present invention includes an electrodeposition unit for electrodepositing an electrodeposited copper foil; a supply unit for supplying a support including a carrier film and a release film formed on the carrier film; a laminating unit for laminating the electrodeposited copper foil supplied from the electrodeposition unit and the support supplied from the supply unit; and a winding unit for winding the copper foil laminated by the laminating unit. The supply unit may include a supply roller on which the carrier film is wound, and a forming mechanism disposed between the supply roller and the laminating unit to form the release film on the carrier film to manufacture the support.

According to the present invention, the following effects can be achieved.

The present invention is implemented so that a support having a carrier film and a release film is attached to the electrodeposited copper foil in a laminating method to manufacture a release copper foil. Accordingly, the present invention can improve the productivity of the deformable copper foil by reducing the process time for manufacturing the deformable copper foil.

The present invention is implemented so as to reduce the number of immersion tanks required to manufacture the deformable copper foil. Accordingly, the present invention can reduce the construction cost of equipment for manufacturing the deformable copper foil, and thus can contribute to lowering the manufacturing cost of the deformable copper foil. In addition, since the present invention can be implemented so that more equipment can be built in a workshop of the same area by reducing the installation area occupied by the workshop, productivity for the molded copper foil can be further improved.

1 is a conceptual diagram of a copper foil manufacturing apparatus according to the prior art;
2 is a schematic perspective view of a copper foil manufacturing apparatus according to the present invention;
3 is a schematic block diagram of a copper foil manufacturing apparatus according to the present invention;
4 is a schematic side cross-sectional view of a release copper foil implemented using an electrodeposited copper foil, a carrier film, and a release film;
5 is a schematic side view of the supply unit and the laminating unit in the copper foil manufacturing apparatus according to the present invention;
6 is a conceptual configuration diagram of a copper foil manufacturing apparatus according to the present invention;

Hereinafter, an embodiment of a copper foil manufacturing apparatus according to the present invention will be described in detail with reference to the accompanying drawings. When describing an embodiment of the present invention, when it is described that a structure is formed "on" or "below" another structure, such a substrate indicates that the structures are in contact with each other, as well as a third structure between these structures. It should be construed as including even the case where the structure is interposed. On the other hand, hatching in FIG. 2 is indicated to distinguish between the electrodeposited copper foil, the carrier film, the carrier film to which the release film is attached, and the release copper foil. In Fig. 2, the forming mechanism included in the supply unit is omitted.

2 to 4 , the copper foil manufacturing apparatus 1 according to the present invention manufactures the copper foil 100 . The copper foil 100 is an electrodeposited copper foil 110 and a carrier film 120 are attached through a release film (130). In this case, the release film 130 may be positioned on the carrier film 120 , and the electrodeposited copper foil 110 may be positioned on the release film 130 . In this way, the copper foil 100 may be implemented as a deformable copper foil. Hereinafter, the copper foil 100 will be referred to as a deformable copper foil 100 and will be described.

In the release copper foil 100, the carrier film 120 may be implemented as a carrier foil manufactured using copper. The carrier film 120 may have stronger rigidity than the electrodeposited copper foil 110 . To this end, the carrier film 120 may function as a support for the electrodeposited copper foil 110 . The carrier film 120 may be attached to one surface of the release film 130 , and the electrodeposited copper foil 110 may be attached to the other surface of the release film 130 . When the copper foil 100 is bonded to the product, the release film 130 and the carrier film 120 are peeled off from the electrodeposited copper foil 110 , and only the electrodeposited copper foil 110 may be bonded to the product.

The copper foil manufacturing apparatus 1 according to the present invention attaches a support 140 having the carrier film 120 and the release film 130 to the electrodeposited copper foil 110 in a laminating method, whereby the release copper foil ( 100) can be prepared. Accordingly, the copper foil manufacturing apparatus 1 according to the present invention can achieve the following operational effects.

First, in the copper foil manufacturing apparatus 1 according to the present invention, in comparison with forming all of a release layer, a copper foil layer, etc. through immersion in a plurality of immersion tanks 13 in the prior art, the release copper foil 100 The process time for manufacturing can be reduced. Since the copper foil manufacturing apparatus 1 according to the present invention directly attaches the support 140 and the electrodeposited copper foil 110 through laminating, in each of the plurality of immersion tanks 13 in the prior art, a release layer, a copper foil layer, etc. This is because the formation time required for this formation can be reduced. Therefore, the copper foil manufacturing apparatus 1 according to the present invention can improve the productivity of the deformable copper foil 100 .

Second, the copper foil manufacturing apparatus 1 according to the present invention is implemented to reduce the number of immersion tanks 13 required for manufacturing the deformable copper foil 100 in the prior art. Accordingly, the copper foil manufacturing apparatus 1 according to the present invention can reduce the construction cost of equipment for manufacturing the deformable copper foil 100 when compared with the prior art, thereby contributing to lowering the manufacturing cost of the deformable copper foil 100 can In addition, the copper foil manufacturing apparatus 1 according to the present invention reduces the installation area occupied in the workshop when compared with the prior art, so that more facilities can be built in the workshop of the same area, so the productivity for the deformable copper foil 100 can be further improved.

To this end, the copper foil manufacturing apparatus 1 according to the present invention may include an electrodeposition unit 2 , a winding unit 3 , a supply unit 4 , and a laminating unit 5 .

2 to 4 , the electrodeposition part 2 is to electrodeposit the electrodeposited copper foil 110 . The electrodeposition part 2 may electrodeposit the electrodeposited copper foil 110 using an electrolytic solution by an electroplating method. The electrodeposition part 2 may include a negative electrode drum 21 and an anode member 22 . When the negative electrode drum 21 and the positive electrode member 22 are energized through the electrolyte and a current flows, copper ions dissolved in the electrolyte may be reduced in the negative electrode drum 21 . Accordingly, the copper foil 200 may be electrodeposited on the surface of the negative electrode drum 21 .

The cathode drum 21 may rotate about a rotation axis. The anode drum 21 can continuously perform an electrodeposition operation of electrodepositing the electrodeposited copper foil 110 on the surface and a peeling operation of detaching the electrodeposited copper foil 110 from the surface while rotating about the rotation axis. The negative electrode drum 21 may be formed in the form of a drum as a whole, but is not limited thereto, and may be formed in a different shape as long as it is capable of continuously performing the electrodeposition operation and the peeling operation while rotating about the rotation axis. may be The cathode drum 21 may be rotated by a driving force generated by a cathode mechanism (not shown).

The anode member 22 conducts electricity with the cathode drum 21 through an electrolyte. The anode member 22 may be disposed below the cathode drum 21 . The anode member 22 may be disposed to be spaced apart from the surface of the cathode drum 21 . The surface of the anode member 22 and the surface of the cathode drum 21 may be formed in the same shape as each other. For example, when the negative electrode drum 21 is formed in a circular rectangular shape to have a curved surface, the positive electrode member 22 may be formed in a semicircular rectangular shape to have a curved surface.

2 to 4 , the winding unit 3 winds up the copper foil laminated by the laminating unit 5 . That is, the winding unit 3 winds the molded copper foil 100 . The electrodeposited copper foil 110 manufactured by the electrodeposition part 2 is laminated with the support 140 by the laminating part 5 to be manufactured into the molded copper foil 100 and then to be wound on the winding part 3 . can The winding unit 3 , the supply unit 4 , and the laminating unit 5 may be coupled to a frame (not shown), respectively. Although not shown, the frame may be installed on the floor surface of the workshop where the copper foil manufacturing apparatus 1 according to the present invention is installed.

The winding unit 3 may include a winding roller 31 . The winding roller 31 may take up the molded copper foil 100 while rotating about a rotation axis. The winding roller 31 may be formed in the form of a drum as a whole, but is not limited thereto, and may be formed in another form as long as it is capable of winding the molded copper foil 100 while rotating about a rotation axis. The winding roller 31 may be rotated by a driving force generated by a winding mechanism (not shown).

A core 32 may be mounted on the winding part 3 . The core 32 may be mounted on the winding roller 31 so as to surround the winding roller 31 . As the winding roller 31 rotates, the molded copper foil 100 may be wound around the core 32 . The core 32 may be detachably mounted to the winding part 3 . Accordingly, when the winding of the deformable copper foil 100 with respect to the core 32 is completed or a defect occurs, the replacement operation of separating the core 32 from the winding part 3 and mounting a new core 32 This can be done. Meanwhile, the core 32 and the winding roller 31 may be integrally formed. In this case, when the winding of the molded copper foil 100 with respect to the core 32 is completed, the core 32 and the winding roller 31 are integrally separated and then transported to a facility for a subsequent process. .

2 to 5 , the supply unit 4 supplies the support 140 . The support 140 includes the carrier film 120 and the release film 130 formed on the carrier film 120 . The supply unit 4 may supply the support 140 to the laminating unit 5 after manufacturing the support 140 by forming the release film 130 on the carrier film 120 .

The supply unit 4 may include a supply roller 41 and a forming mechanism 42 .

The supply roller 41 supplies the carrier film 120 . The carrier film 120 may be wound on the supply roller 41 . The supply roller 41 may supply the carrier film 120 to the forming mechanism 42 by unwinding the carrier film 120 while rotating about the rotation shaft. The supply roller 41 may be formed in the form of a drum as a whole, but is not limited thereto, and may be formed in another form as long as it is capable of unwinding the carrier film 120 while rotating about a rotation axis. The supply roller 41 may be rotated by a driving force generated by a supply mechanism (not shown).

The forming mechanism 42 forms the release film 130 on the carrier film 120 . The forming mechanism 42 may be disposed between the supply roller 41 and the laminating unit 5 . Accordingly, the forming mechanism 42 forms the release film 130 on the carrier film 120 to manufacture the support 140 , and then supplies the support 140 to the laminating unit 5 . can The forming mechanism 42 may form the release film 130 on the carrier film 120 by an immersion method. To this end, the forming mechanism 42 may include an immersion tank 421 and an immersion roller 422 .

The immersion tank 421 is to accommodate the immersion liquid for forming the release film (130). The immersion tank 421 may be disposed between the supply roller 41 and the laminating unit 5 . Using the immersion liquid contained in the immersion tank 421, the release film 130 is polyethylene terephthalate (PET, polyethylene terephthalate), polyimide (PI, polyimide), polycarbonate (PC, polycarbonate), polypropylene ( PP, polypropylene), polymethyl methacrylate (PMMA, Poly(methyl methacrylate)), polycaprolactone, polystyrene, propylene carbonate, ethylene carbonate, dimethylcarbonate ), diethyl carbonate (diethylcarbonate), may be formed to include at least one selected material of the polymer plastic. The release film 130 may be formed of a single-layer or multi-layer adhesive sheet. When implemented as a multi-layer pressure-sensitive adhesive sheet, the first release film on one side of the pressure-sensitive adhesive layer and the second release film on the other side of the pressure-sensitive adhesive layer may be respectively laminated. The multi-layer pressure-sensitive adhesive sheet is configured by laminating a release sheet having a relatively low peel force and a release sheet having a relatively high peel force on both sides of the adhesive layer, and may be selected according to the surface of an object to be contacted according to workability and the like.

The immersion roller 422 is for immersing the carrier film 120 in the immersion liquid contained in the immersion tank 421 . The immersion roller 422 may supply the carrier film 120 unwound from the supply roller 41 to the laminating unit 5 after immersing the carrier film 120 in the immersion solution accommodated in the immersion tank 421 . While the carrier film 120 is immersed in the immersion liquid by the immersion roller 422 , the release film 130 is formed on the carrier film 120 , whereby the support 140 may be manufactured. The immersion roller 422 may be arranged to be immersed in the immersion liquid contained in the immersion tank 421 . The immersion roller 422 may rotate about a rotation axis. In this case, the immersion roller 422 may be rotatably coupled to the immersion tank 421 or a device located in the vicinity thereof. The immersion roller 422 may be formed in a drum shape as a whole.

The forming mechanism 42 may include a plurality of auxiliary rollers 423 and 423'. Among the auxiliary rollers 423 and 423 ′, a first auxiliary roller 423 may be disposed between the supply roller 41 and the immersion roller 422 . Accordingly, the first auxiliary roller 423 may guide the carrier film 120 unwound from the supply roller 41 to be conveyed toward the immersion roller 422 . The first auxiliary roller 423 may be disposed above the immersion liquid contained in the immersion tank 421 . Among the auxiliary rollers 423 and 423 ′, a second auxiliary roller 423 ′ may be disposed between the immersion roller 422 and the laminating unit 5 . Accordingly, the second auxiliary roller 423 ′ may guide the support 140 passing through the immersion roller 422 to be conveyed toward the laminating unit 5 . The second auxiliary roller 423 ′ may be disposed above the immersion liquid contained in the immersion tank 421 .

In this way, the supply unit 4 forms the release film 130 on the carrier film 120 to manufacture the support 140 , and then supplies the support 140 to the laminating unit 5 . have. In this case, the supply unit 4 may supply the support 140 such that the side to which the carrier film 120 is not attached faces the electrodeposited copper foil 110 among both surfaces of the release film 130 . . For example, when the carrier film 120 is attached to one surface of the release film 130 , the supply unit 4 may be configured such that the other surface of the release film 130 faces the electrodeposited copper foil 110 . can supply

2 to 5 , the laminating unit 5 is to laminate the electrodeposited copper foil 110 supplied from the electrodeposition unit 2 and the support 140 supplied from the supply unit 4 . In this case, the laminating part 5 is attached to the electrodeposited copper foil 110 peeled from the negative electrode drum 21 and the carrier film 120 unwound from the supply roller 41 by the forming mechanism 42 by the release film. The support 140 on which 130 is formed may be laminated. By laminating the electrodeposited copper foil 110 and the support 140 , the molded copper foil 100 may be manufactured. The laminating part 5 may be disposed between the electrodeposition part 2 and the winding part 3 . In this case, in the copper foil manufacturing apparatus 1 according to the present invention, the electrodeposited copper foil 110 supplied from the electrodeposition unit 2 and the support body 140 supplied from the supply unit 4 passed through the laminating unit 5 . It may be implemented to be wound on the winding part 3 later. In this way, the copper foil manufacturing apparatus 1 according to the present invention includes an electrodeposition operation and a peeling operation for the electrodeposited copper foil 110 through a roll to roll method, an unwinding operation for the carrier film 120, and the electrodeposited copper foil It is implemented so as to continuously perform a laminating operation for 110 and the support 140 , and a winding operation for the molded copper foil 100 . Therefore, the copper foil manufacturing apparatus 1 according to the present invention can further improve the productivity of the deformable copper foil 100 .

The laminating unit 5 may include a support roller 51 and a laminating roller 52 .

The support roller 51 supports the electrodeposited copper foil 110 and the support 140 . The support roller 51 may serve to support the electrodeposited copper foil 110 and the support 140 when the electrodeposited copper foil 110 and the support 140 are laminated. The support roller 51 may be rotated about a rotation axis. The support roller 51 may be formed in the form of a drum as a whole, but is not limited thereto, and may be formed in another form as long as it can support the electrodeposited copper foil 110 and the support 140 . The support roller 51 may be rotated by a driving force generated by a support mechanism (not shown).

The support roller 51 may include a support member 511 . The support member 511 is in contact with any one of the electrodeposited copper foil 110 and the support 140 . When the electrodeposited copper foil 110 is in contact with the laminating roller 52 , the support member 511 may be in contact with the support 140 . When the support 140 is in contact with the laminating roller 52 , the support member 511 may be in contact with the electrodeposited copper foil 110 .

The support roller 51 may include a support body 512 . The support body 512 supports the support member 511 . The support member 511 may be coupled to the support body 512 so as to surround the surface of the support body 512 . The support body 512 may be located inside the support member 511 . The support mechanism may rotate the support member 511 by rotating the support body 512 .

The laminating roller 52 provides a pressing force. The laminating roller 52 may laminate the electrodeposited copper foil 110 and the support 140 by providing a pressing force toward the support roller 51 . The electrodeposited copper foil 110 and the support body 140 pass between the laminating roller 52 and the support roller 51 while passing through the pressing force provided by the laminating roller 52 and the support roller 51 provided by the support roller 51 . By laminating using a supporting force, the molded copper foil 100 may be manufactured. The laminating roller 52 may be moved between a first direction toward the support roller 51 and a second direction spaced apart from the support roller 51 . The laminating roller 52 may be rotated about a rotation axis. The laminating roller 52 may be formed in the form of a drum as a whole, but is not limited thereto, and may be formed in another form as long as it can press the electrodeposited copper foil 110 and the support 140 . The laminating roller 52 may be moved in the first direction and the second direction by a driving force generated by a laminating mechanism (not shown). The laminating roller 52 may be rotated by a driving force generated by the laminating mechanism (not shown).

The laminating roller 52 may include a pressing member 521 . The pressing member 521 is in contact with any one of the electrodeposited copper foil 110 and the support 140 . Among the electrodeposited copper foil 110 and the support body 140 , the pressing member 521 may be in contact with one other than the one in contact with the support roller 51 . The pressing member 521 may be in contact with any one of the electrodeposited copper foil 110 and the support 140 to press the support member 511 toward the support member 511 .

The pressing member 521 may be formed of a stretchable material. Accordingly, since the copper foil manufacturing apparatus 1 according to the present invention can strongly press the electrodeposited copper foil 110 and the support 140 by using the elasticity of the pressing member 521, the deformable copper foil manufactured through laminating (100) can improve the quality. In addition, the copper foil manufacturing apparatus 1 according to the present invention uses the elasticity of the pressing member 521 to cause damage or damage to the electrodeposited copper foil 110 and the support 140 by pressure or to leave traces. it can be prevented Therefore, the copper foil manufacturing apparatus 1 according to the present invention can manufacture the deformable copper foil 100 having a more improved quality. For example, the pressing member 521 may be formed of rubber.

Meanwhile, the support member 511 may be formed of a material having a stronger rigidity than that of the pressing member 521 . Accordingly, the copper foil manufacturing apparatus 1 according to the present invention uses the elasticity of the pressing member 521 and the firm support force of the supporting member 511 to further improve the quality of the molded copper foil 100 manufactured through lamination. can For example, the support member 511 may be formed of a stainless metal (SUS, Steel Use Stainless).

The laminating roller 52 may include a pressing body 522 . The pressing body 522 supports the pressing member 521 . The pressing member 521 may be coupled to the pressing body 522 so as to surround the surface of the pressing body 522 . The pressing body 522 may be located inside the pressing member 521 . The laminating mechanism may move the pressing member 521 in the first direction and the second direction by moving the pressing body 522 in the first direction and the second direction. The laminating mechanism may rotate the pressing member 521 by rotating the pressing body 522 .

2 to 5 , the copper foil manufacturing apparatus 1 according to the present invention may include a conveying unit 6 .

The transport unit 6 is provided for transport. The carrying unit 6 may transport the electrodeposited copper foil 110 , the support 140 , or the deformable copper foil 100 depending on the arrangement. In the case of the transport unit 6 disposed to transport the electrodeposited copper foil 110 , the electrodeposited copper foil 110 may be transported from the electrodeposition unit 2 to the laminating unit 5 . In this process, a washing operation of washing the electrodeposited copper foil 110 , a drying operation of drying the electrodeposited copper foil 110 , a rust prevention operation of performing a rust prevention treatment on the electrodeposited copper foil 110 , etc. may be performed. In the case of the transport unit 6 disposed to transport the carrier film 120 , the carrier film 120 may be transported from the supply roller 41 toward the forming mechanism 42 . In the case of the transport unit 6 disposed to transport the support 140 , the support 140 may be transported from the forming mechanism 42 toward the laminating part 5 . In the case of the carrying unit 6 disposed to transport the molded copper foil 100 , the molded copper foil 100 may be transported from the laminating part 5 to the winding part 3 . The carrying part 6 may be coupled to the frame.

The conveying unit 6 may include a conveying roller 61 . The conveying roller 61 may convey the electrodeposited copper foil 110 , the support 140 , or the deformable copper foil 100 while rotating about a rotating shaft. The conveying part 6 may include a plurality of the conveying rollers 61 . In this case, the conveying roller 61 for transporting the electrodeposited copper foil 110 may be disposed between the electrodeposition part 2 and the laminating part 5 . A conveying roller 61 for conveying the carrier film 120 may be disposed between the supply roller 41 and the forming mechanism 42 . The conveying roller 61 for conveying the support 140 may be disposed between the forming mechanism 42 and the laminating unit 5 . The conveying roller 61 for conveying the molded copper foil 100 may be disposed between the laminating unit 5 and the winding unit 3 . The conveying roller 61 may be formed in the form of a drum as a whole, but is not limited thereto, and may be formed in another form as long as it can implement a conveying function while rotating around a rotating shaft. At least one of the conveying rollers 61 may be rotated by a driving force generated by a conveying mechanism (not shown).

2 to 5 , the electrodeposited copper foil manufacturing apparatus 1 according to the present invention may include a cutting part 7 .

The cut part 7 is disposed between the laminating part 5 and the winding part 3 . The cutting part 7 may cut both sides based on the width direction of the laminated copper foil. That is, the cutting part 7 may cut both sides of the deformable copper foil 100 . Accordingly, both edges of the electrodeposited copper foil 110 that are relatively non-uniform based on the width direction of the deformable copper foil 100 may be cut. The remaining copper foil 100 except for both sides of the molded copper foil 100 cut by the cutting part 7 may be wound around the winding part 3 . Both sides of the molded copper foil 100 delivered by the cutting part 7 may be recovered by a recovery part (not shown).

The cutting part 7 may include a cutting roller 71 rotating about a rotation axis, and a cutting member 72 for cutting a part of the molded copper foil 100 moving along the cutting roller 71 . The cutting part 7 may include a plurality of the cutting members 72 . The cutting members 72 may cut both edges of the deformable copper foil 100 based on the width direction of the deformable copper foil 100 .

Referring to FIG. 6 , the copper foil manufacturing apparatus 1 according to the present invention may include a plasma processing unit 81 .

The plasma processing unit 81 performs plasma processing on the support 140 . The plasma processing unit 81 may be disposed between the forming mechanism 42 and the laminating unit 5 . Accordingly, while the support 140 is transported from the forming device 42 to the laminating unit 5 , plasma treatment of the support 140 is performed using the plasma generated by the plasma processing unit 81 . can be made Plasma is oxygen (O ₂ ), hydrogen (H ₂ ), argon (Ar), nitrogen (N ₂ ), helium (He), hydrogen / argon (H ₂ /Ar), nitrogen / argon (N ₂ /Ar), Oxygen/argon (O ₂ /Ar), helium/argon (He/Ar), tetraprolomethane (CF ₄ ), methane (CH ₄ ), ethane (C ₂ H ₆ ), tetraprolomethane/argon (CF ₄ / Ar), methane / argon (CH ₄ /Ar), methane / hydrogen (CH ₄ /H ₂ ), ethane / hydrogen (C ₂ H ₆ /H ₂ ) any one of a single gas or a mixture of one or more can be done The plasma processing unit 81 may be coupled to the frame.

Referring to FIG. 6 , the copper foil manufacturing apparatus 1 according to the present invention may include a first processing unit 82 .

The first processing unit 82 performs washing and drying processing on the electrodeposited copper foil 110 . The first processing unit 82 may be disposed between the electrodeposition unit 2 and the laminating unit 5 . Accordingly, in the process of transferring the electrodeposited copper foil 110 from the electrodeposition unit 2 to the laminating unit 5, the first processing unit 82 performs the washing treatment and drying treatment for the electrodeposited copper foil 110 by the first processing unit 82. can be done The water washing treatment includes acid cleaning to remove impurities (eg, a resin component or natural oxide) on the surface of the electrodeposited copper foil 110 and water cleaning for removing an acid solution used for pickling. ) can be performed sequentially. The first processing unit 82 may be coupled to the frame.

Referring to FIG. 6 , the copper foil manufacturing apparatus 1 according to the present invention may include a rust preventive treatment unit 83 .

The rust prevention processing unit 83 is to perform the rust prevention processing for the molded copper foil (100). The rust preventive treatment unit 83 may be disposed between the laminating unit 5 and the winding unit 3 . Accordingly, in the process in which the deformable copper foil 100 is transported from the laminating unit 5 to the winding unit 3, the antirust treatment for the deformable copper foil 100 may be performed by the antirust treatment unit 83. have. The rust preventive treatment unit 83 may perform a rust preventive treatment on the molded copper foil 100 using a rust preventive solution. For example, the rust preventive liquid may be chromium (Chrom, Cr) or a liquid containing chromium. Accordingly, the anti-rust treatment may be performed by chromium plating on the deformable copper foil 100 by the anti-rust treatment unit 83 . In this case, in the process of transporting the molded copper foil 100 to the outside of the immersion tank after being immersed in the rust preventive solution contained in the immersion tank by the rust prevention rollers, the molded copper foil 100 may be subjected to rust prevention treatment. Although not shown, the anti-rust treatment unit 83 may perform the anti-rust treatment on the deformable copper foil 100 by spraying the anti-rust solution on the deformable copper foil 100 . The rust prevention processing unit 83 may be coupled to the frame.

Referring to FIG. 6 , the copper foil manufacturing apparatus 1 according to the present invention may include a second processing unit 84 .

The second processing unit 84 performs washing and drying processing on the molded copper foil 100 . The second processing unit 84 may be disposed between the rust prevention processing unit 83 and the winding unit 3 . Accordingly, in the process in which the molded copper foil 100 is transported from the antirust processing unit 83 to the winding unit 3 , the molded copper foil 100 is washed with water and dried by the second processing unit 84 . processing may be made. The water washing treatment may be performed by sequentially performing acid cleaning to remove impurities on the surface of the release copper foil 100 and water cleaning to remove an acidic solution used for pickling. The second processing unit 84 may be coupled to the frame. When the second processing unit 84 is provided, the rust prevention processing unit 83 may be disposed between the laminating unit 5 and the second processing unit 84 . Meanwhile, when the second processing part 84 is provided, the cutting part 7 may be disposed between the second processing part 84 and the winding part 3 .

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and it is common in the technical field to which the present invention pertains that various substitutions, modifications and changes are possible without departing from the technical spirit of the present invention. It will be clear to those who have the knowledge of

1: copper foil manufacturing apparatus 2: electrodeposition part
21: negative drum 22: positive electrode member
3: winding part 31: winding roller
32: core 4: supply part
41: supply roller 42: forming mechanism
421: immersion tank 422: immersion roller
423: first auxiliary roller 423': second auxiliary roller
5: laminating unit 51: support roller
511: support member 512: support body
52: laminating roller 521: pressing member
522: pressurized body 6: transport part
61: transport roller 7: cutting part
71: cutting roller 72: cutting member
81: plasma processing unit 82: first processing unit
83: rust prevention processing unit 84: second processing unit
100: copper foil 110: electrolytic copper foil
120: carrier film 130: release film
140: support

Claims (9)

Electrodeposition part (2) for electrodeposition of the electrodeposited copper foil (110);
a supply unit (4) for supplying a carrier film (120) and a support body (140) including a release film (130) formed on the carrier film (120);
a laminating unit 5 for laminating the electrodeposited copper foil 110 supplied from the electrodeposition unit 2 and the support 140 supplied from the supply unit 4;
a winding unit 3 for winding the copper foil 100 laminated by the laminating unit 5;
a plasma processing unit 81 for performing plasma processing on the support 140;
a first processing unit 82 disposed between the electrodeposition unit 2 and the laminating unit 5 to perform a washing treatment and drying treatment for the electrodeposited copper foil 110;
a rust preventive treatment unit 83 disposed between the laminating unit 5 and the winding unit 3 to perform a rust preventive treatment on the copper foil 100; and
and a second treatment unit 84 disposed between the rust prevention treatment unit 83 and the winding unit 3 to perform washing treatment and drying treatment for the copper foil 100,
The supply unit 4 is disposed between the supply roller 41 on which the carrier film 120 is wound, and the supply roller 41 and the laminating unit 5 to provide the carrier film 120 with the release film. and a forming mechanism (42) for forming the support (140) by forming (130);
The plasma processing unit (81) is disposed between the forming mechanism (42) and the laminating unit (5) to perform plasma processing on the support (140). According to claim 1, wherein the laminating part (5)
a support roller 51 for supporting the electrodeposited copper foil 110 and the support 140; and
and a laminating roller (52) for laminating the electrodeposited copper foil (110) and the support (140) by providing a pressing force toward the support roller (51). 3. The method of claim 2,
The laminating roller 52 includes a pressing member 521 in contact with any one of the electrodeposited copper foil 110 and the support 140,
The pressure member 521 is a copper foil manufacturing apparatus, characterized in that formed of a material that can be stretched (伸縮). 4. The method of claim 3,
The pressure member (521) is a copper foil manufacturing apparatus, characterized in that formed of rubber (Rubber). 5. The method of claim 3 or 4,
The support roller 51 includes a support member 511 in contact with any one of the electrodeposited copper foil 110 and the support body 140 ,
The support member (511) is a copper foil manufacturing apparatus, characterized in that formed of a material having a stronger rigidity than the pressing member (521). According to claim 1,
The electrodeposition part 2 includes a negative electrode drum 21 for electrodepositing an electrodeposited copper foil 110 by an electroplating method using an electrolyte, and an anode member 22 that conducts electricity with the negative electrode drum 21 through the electrolyte. including,
The laminating part 5 is formed on the electrodeposited copper foil 110 peeled from the negative electrode drum 21 and the carrier film 120 unwound from the supply roller 41 by the forming mechanism 42 by the release film 130 . Copper foil manufacturing apparatus, characterized in that for laminating the formed support (140). According to claim 1, wherein the forming mechanism (42)
an immersion tank 421 disposed between the supply roller 41 and the laminating part 5; and
After immersing the carrier film 120 unwound from the supply roller 41 in the immersion liquid contained in the immersion tank 421, it comprises an immersion roller 422 for supplying it to the laminating unit 5 Copper foil manufacturing equipment. According to claim 1,
a cutout (7) disposed between the laminating part (5) and the winding part (3);
The cut part 7 cuts both sides based on the width direction of the laminated copper foil 100,
Copper foil manufacturing apparatus, characterized in that the remaining copper foil (100) except for both sides of the copper foil (100) cut by the cutting portion (7) is wound around the winding unit (3). Electrodeposition part (2) for electrodeposition of the electrodeposited copper foil (110);
a supply unit (4) for supplying a carrier film (120) and a support body (140) including a release film (130) formed on the carrier film (120);
a laminating unit 5 for laminating the electrodeposited copper foil 110 supplied from the electrodeposition unit 2 and the support 140 supplied from the supply unit 4;
a plasma processing unit 81 for performing plasma processing on the support 140; and
and a winding unit (3) for winding the copper foil (100) laminated by the laminating unit (5),
The supply unit 4 is disposed between the supply roller 41 on which the carrier film 120 is wound, and the supply roller 41 and the laminating unit 5 to provide the carrier film 120 with the release film. and a forming mechanism (42) for forming the support (140) by forming (130);
The plasma processing unit (81) is disposed between the forming mechanism (42) and the laminating unit (5) to perform plasma processing on the support (140).

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